Extraocular muscle morphogenesis and gene expression are regulated by Pitx2 gene dose.

PURPOSE: PITX2 gene dose plays a central role in Axenfeld-Rieger syndrome. The purpose of this study was to test the hypothesis that the effects of Pitx2 gene dose on eye development can be molecularly dissected in available Pitx2 mutant mice. METHODS: A panel of mice with Pitx2 gene dose ranging from wild-type (+/+) to none (-/-) was generated. Eye morphogenesis was assessed in animals with each Pitx2 gene dose. We also compared global gene expression in eye primordia taken from e12.5 Pitx2+/+, Pitx2+/-, Pitx2-/- embryos using gene microarrays. The validity of microarray results was confirmed by qRT-PCR. RESULTS: Morphogenesis of all extraocular muscle bundles correlated highly with Pitx2 gene dose, but there were some differences in sensitivity among muscle groups. Superior and inferior oblique muscles were most sensitive and disappeared before the four rectus muscles. Expression of muscle-specific genes was globally sensitive to Pitx2 gene dose, including the muscle-specific transcription factor genes Myf5, Myog, Myod1, Smyd1, Msc, and Csrp3. CONCLUSIONS: Pitx2 gene dose regulates both morphogenesis and gene expression in developing extraocular muscles. The expression of key muscle-specific transcription factor genes is regulated by Pitx2 gene dose, suggesting that sufficient levels of PITX2 protein are essential for early initiation of the myogenic regulatory cascade in extraocular muscles. These results document the first ocular tissue affected by Pitx2 gene dose in a model organism, where the underlying mechanisms can be analyzed, and provide a paradigm for future experiments designed to elucidate additional effects of Pitx2 gene dose during eye development.

Regulation of spindle formation by active mitogen-activated protein kinase and protein phosphatase 2A during mouse oocyte meiosis.

Mitogen-activated protein kinase (MAPK) and protein phosphatase 2A (PP2A) regulate oocyte meiosis, yet little is known regarding their mechanisms of action. This study addressed the functional importance of active MAPK and PP2A in regulating oocyte meiosis. Experiments were conducted to identify MAPK activation, PP2A activity, intracellular enzyme trafficking, and ultrastructural associations during meiosis. Questions of requisite kinase and/or phosphatase activity and chromatin condensation, microtubule polymerization, and spindle formation were addressed. At the protein level, MAPK and PP2A were present in constant amounts throughout the first meiotic division. Both MAPK and PP2A were activated following germinal vesicle breakdown (GVBD) in conjunction with metaphase I development. Immunocytochemical studies confirmed the absence of active MAPK in germinal vesicle-intact (GVI) and GVBD oocytes. At metaphase I and during the metaphase I/metaphase II transition, activated MAPK colocalized with microtubules, poles, and plates of meiotic spindles. Protein phosphatase 2A was dispersed evenly throughout the GVI oocyte cytoplasm. Throughout the metaphase I/metaphase II transition, PP2A colocalized with microtubules of meiotic spindles. Both active MAPK and PP2A associated with in vitro-polymerized microtubules, suggesting that active MAPK and PP2A locally regulate spindle formation. Inhibition of MAPK activation resulted in compromised microtubule polymerization, no spindle formation, and loosely condensed chromosomes. Treatment with okadaic acid (OA) or calyculin-A (CL-A), which inhibits oocyte cytoplasmic PP2A, caused an absence of microtubule polymerization and spindles, even though MAPK activity was increased under these treatment conditions. Thus, active MAPK is required, but is not sufficient, for normal meiotic spindle formation and chromosome condensation. In addition, the oocyte OA/CL-A-sensitive PP, presumably PP2A, is essential for microtubule polymerization and meiotic spindle formation.